WO2004017483A1 - Method and device for monitoring fault currents in an electric ac mains - Google Patents

Abstract

The invention relates to a method for monitoring fault currents in an electric AC mains having a predetermined mains frequency. According to the invention, current values of electric currents to be monitored are recorded (12a 12d), after which the recorded current values are converted into digitized current values (14). Afterwards, these digitized current values are used to calculate (16) cumulative current values, from which blocks comprised of the cumulative current values are formed (18) according to the phase position of a mains voltage signal. The blocks are then split (24) into spectral components. The spectral components of the blocks are then monitored (36) with regard to an exceeding of spectral limit values in order to evaluate the danger of the fault current.

Description

Method and device for monitoring residual current in an electrical AC network

description

The present invention relates to residual current monitoring in an electrical AC network, and in particular to the spectral and in-phase detection of absolute and relative currents for the hazard assessment of residual currents and for the assessment of the hazard potential of residual currents for people and material.

In electrical installation technology, the assessment of the hazard potential by an electrical system, such as. B. an electrical AC network, performed on the people on the basis of instantaneous values of the currents to be monitored in the AC network. This applies both to absolute values and to relative and / or differential values of the currents to be monitored, these current values also being referred to as fault currents. This type of hazard detection is used in the form of residual current circuit breakers, which are also referred to as FL switches and which measure the differential current between a forward and a return conductor.

An essential feature of every fault current circuit breaker is the so-called summation current transformer. All current-carrying conductor of an electrical system, including the neutral conductor, are in the same direction and guided together by the sen ^¬ converter. Normal operating currents have no effect on this converter, since their sum always gives a value of "zero", ie there is no residual current. However, if a fault current, which is caused, for example, by a body connection, flows out of the closed circuit to ground, the magnetic balance of the transducer is disturbed by the amount of the fault current flowing to ground (earth). In this case, the converter is magnetized and instantly causes the all-pole switch-off of the residual current circuit breaker via a highly sensitive release.

Residual current circuit breakers therefore measure the AC component of the residual current, the residual current being classified as more or less dangerous according to its amount. With this very widespread type of personal and / or material protection, however, the direct current component of the fault current is not recorded and therefore cannot be evaluated correctly.

International patent application W098 / 58432, for example, describes a hazard detection system for assessing the hazard potential due to fault currents for people and materials, whereby there is an analog method between capacitive reactive fault currents, to which a low risk potential for people is assigned, and active fault currents, to which a high risk potential for humans is differentiated. In addition, a distinction is made in the method described there between an AC component and a DC component. The AC component is broken down into an active and a reactive current via the associated phase. This increases the tolerance to capacitive reactive currents, which are classified as potentially less dangerous because they cannot come from a body current. This makes it possible to trigger at very low active fault currents. men _to achieve, while at the same time there is a relatively high tolerance to capacitive fault currents.

In the international patent application mentioned, a possible approach is also presented in order to also be able to record and evaluate direct currents. Direct currents no longer change the behavior for alternating currents, whereby alternating currents can be evaluated in the correct phase. However, since a phase relationship in the strict sense is only defined for onofrequency signals, higher-frequency currents are incorrectly evaluated with the phase related to the mains frequency (e.g. 50 Hz). In particular, pulse-shaped currents with signal components at higher frequencies, such as those caused by modern switching power supplies for computers, televisions, etc. and by phase control for drilling machines, electric cookers, dimmers, etc., lead to problems in this evaluation, since they are not recorded separately.

Although it is possible to carry out a frequency-dependent weighting of the fault current, this weighting must, however, be implemented analogously by means of complex filters. In addition, the weighted total signal for the AC ^{component is subsequently separated} into an active and a reactive current ^component without taking into account the spectral composition. This is done e.g. B. also in cases in which there is no portion at all with the mains frequency in the measured fault current, and consequently leads to serious erroneous evaluations of the fault current, which in turn severely impairs a correct and reliable assessment of the hazard potential for people and material.

The disadvantages of currently used residual current circuit breakers (Fl switches) according to the prior art are based on the fact that often only the AC component of the fault current and this is only measured according to its amount. Since the phase of the measured AC component of the fault current is not taken into account, there can essentially be no division into an active and reactive component of the fault current. In the case of a very low switch-off threshold of the residual current circuit breaker designed for human protection, this therefore leads to relatively frequent false tripping of the protective device. Raising the trigger threshold reduces the frequency of

False triggering, but also the protective effect for humans.

Furthermore, direct currents in the in house installation technology, z. B. for bathrooms, prescribed type of residual current circuit breakers either not recognized at all or only inadequately. Protection of the people involved against direct currents cannot therefore be adequately achieved, although the frequency of such superimposed direct currents is currently increasing again. Of even greater importance for a remaining hazard potential is the fact that the toroidal core of the summation current transformer used in the circuit breakers can saturate when the direct current load is imperceptible from the outside and the protective effect can therefore be reduced or even eliminated with alternating currents. Therefore, conventional ground fault circuit interrupter provide in this case, rather than a major threat protection for Men ^¬ rule is because the supposed protection is no longer available (from outside imperceptible).

So-called pulse current sensitive circuit breakers represent a possible approach to reducing this problem. These circuit breakers can detect pulsating direct currents. Pure direct currents cannot be measured by these pulse current sensitive circuit breakers either.

Based on this prior art, the object of the present invention is to provide an improved concept for residual current monitoring in an electrical AC network in order to ensure a safer and more reliable assessment of the hazard potential for people and material by means of residual current monitoring.

This object is achieved by a method for residual current monitoring according to claim 1 and by a device for residual current monitoring according to claim 11.

In the method according to the invention for residual current monitoring in an electrical AC network with a predetermined network frequency, current values of electrical currents to be monitored are first detected. The detected current values are then converted into discrete, digitized current values, sum current values being calculated from the digitized current values. Blocks are formed from the total current values depending on the phase position of a mains voltage signal, whereupon these blocks are broken down from the total current values into their spectral components. Finally, the spectral components of the blocks are monitored to determine whether the spectral limit values have been exceeded in order to assess the dangerousness of the fault current.

The device according to the invention for residual current monitoring in an electrical AC network with a predetermined A network frequency comprises a device for detecting current values of electrical currents to be monitored, a device for converting the detected current values into digitized current values, a device for calculating total current values from the digitized current values, and a device for forming blocks from the total current values in Dependence on the phase position of a mains voltage ^signal , a device for spectrally breaking up the blocks into spectral components, and a device for monitoring the spectral components of the blocks with regard to exceeding spectral limit values for evaluating the dangerousness of the fault current.

The present invention is based on the knowledge that a method for the spectral decomposition and splitting of signals into its individual spectral components by means of a Fourier transformation can be used as part of the risk assessment of a fault current in fault current monitoring in an electrical AC network, it being advantageous if one or more suitable weighting functions can be found and used for the hazard assessment of the fault current.

The signals, ie the electrical currents to be monitored in an electrical AC network, which are to be used for the actual risk assessment, are first detected with appropriate sensors, then amplified (if necessary) and finally converted into a discrete digital value. For the residual current monitoring, a total current is now calculated from the digital values of the individual currents. The total current values are then divided into blocks with a preferably fixed length in synchronism with the frequency of the mains voltage signal. This can overlap or simply done sequentially. A block always contains all current values during a period of the mains voltage signal, for example between two similar zero crossings of the mains voltage. These blocks of the total current values are then broken down into their spectral components by means of a discrete Fourier transformation.

At this point, can now easily get a differing ^¬ che weight of the active and reactive current component of the Su men- current, that is the fault current, are carried out by the real or imaginary part is to multiply the respective spectral line of the fault current with an appropriate weighting factor. For example, to double the tripping threshold for capacitive (or inductive) reactive currents, you have to multiply the imaginary part of the mains frequency component (ie the 50Hz component at a 50Hz mains frequency) by 0.5.

Following the optional weighting, limit value monitoring of the spectral components of the blocks is then carried out with regard to exceeding spectral limit values in order to assess the dangerousness of the fault current.

Now if the signal to be measured, i. H. If the fault current contains a frequency of 50 Hz (mains frequency), then the discrete Fourier transformation is used to determine exactly the correct value of the spectral line in question.

However, if the signal frequency of the total current is, for example, at a frequency of 75 Hz (assuming a line frequency of 50 Hz), ie the signal frequency of the fault current is not an integral multiple of the line fre quenz, then the switch-off threshold of the residual current monitoring method is raised significantly at this frequency (75 Hz) due to the lower sensitivity of the 50 Hz line (and the neighboring 100 Hz line). The switch-off threshold between the spectral lines thus clearly depends on the signal frequency of the total current, which leads to a correction of the detection sensitivity for the fault currents with frequencies in a further aspect of the method for fault current monitoring in an electrical AC network after the blocks have been broken down into spectral components is carried out between successive multiples of the network frequency by combining spectral amplitude values which are assigned to the neighboring spectral lines. Such a spectral combination is generally referred to below as "imaging".

With this so-called "mapping", the stringing together of several spectral lines leads to an essentially constant switch-off value. One possible realization for such a mapping now consists in the two amounts or squares of amounts of respectively adjacent spectral lines, which have an integral multiple of the network frequency, to add after the discrete Fourier transform.

The resulting value is then a good measure with an error of at most about + 5% for the existing signal amplitude between the two adjacent discrete frequencies, i. H. neighboring integer multiples of the network frequency.

This gives a statement about the sum of the existing signal amplitudes in the interval between the two neighboring frequencies. This total value can then be monitored, for example, by a comparator for exceeding a specific, predetermined limit value.

It is also possible to implement different switch-off thresholds for different frequency ranges. This means that high-frequency fault currents, which originate, for example, from switched elements, can be weighted less in order to reduce the frequency of false tripping without reducing safety for people.

With the method according to the invention, it is also possible to specifically detect and evaluate direct currents, since direct current-capable sensors can now also be used for signal detection by individual sensors.

With the possibility of being able to implement any spectral weighting functions, it is also possible to emulate the characteristic of the physiological risk to humans from fault currents depending on the frequency. When this is carried out, on the one hand, a high level of safety for humans is combined with an optimally low frequency for false tripping and thus with a high level of acceptance of the protection system.

It can be seen that the inventive concept for residual current monitoring in an electrical AC network provides a number of advantages over previously known methods for residual current monitoring. The main advantage over the prior art is therefore that with the inventive concept for residual current monitoring now a targeted and so that the hazard potential of all spectral components of fault currents can be correctly assessed in accordance with the physiological findings. This means that the greatest possible safety for the user can be reconciled with the smallest possible number of false triggers for residual current monitoring.

Even in critical applications such as B. systemic high fault currents at certain frequencies, such as. B. the PWM frequency in three-phase drives (PWM = pulse width modulation), in which a protective function could no longer be adequately guaranteed with conventional fault current protection arrangements, the concept according to the invention for fault current monitoring for assessing the dangerousness of the fault current can still achieve sufficiently good protection by completely hiding or weighting the relevant frequency or frequencies (and only these). As long as the problematic active current parts are not on the mains frequency line, i. H. For example, the 50 Hz line, effective protection for people can still be obtained.

Preferred exemplary embodiments of the present invention are explained in more detail below with reference to the accompanying drawings. Show it:

Fig. 1 is a flowchart of the method for residual current monitoring in an AC network according to a preferred embodiment of the present

Invention; 2 shows the magnitude of a spectral line for signals with different frequencies but constant amplitude;

3 shows the magnitude of the spectral weighting between two adjacent spectral lines (50 Hz and 100 Hz spectral line) after a discrete Fourier transformation according to an exemplary embodiment of the present invention; and

Fig. 4 is a schematic diagram of the entire spectral combination (overlap) in the range from direct current (DC) to 750 Hz according to an embodiment of the present invention.

A preferred exemplary embodiment of the method for residual current monitoring in an electrical AC network with a predetermined network frequency according to the present invention will now be described with reference to FIG. 1.

The basic procedure for multi-channel residual current monitoring, ie residual current monitoring, in a grounded, single-phase or multi-phase electrical AC network with a predetermined network frequency is described on the basis of the flow diagram of FIG. 1, with a 4-channel residual current monitoring in the exemplary embodiment shown in FIG. 1 is carried out. It should be noted that the present invention is applicable to residual current monitoring with any number of channels. Furthermore, the following description assumes a line frequency of 50 Hz gene, it should be noted that the present invention is applicable to any network frequencies.

As shown in boxes 12a-d of the flow chart of FIG. 1, the method according to the invention for residual current monitoring in an electrical AC network according to the preferred exemplary embodiment begins with the four currents to be monitored, for example the currents of three network conductors and, using current sensors the current of a neutral conductor, with the correct sign. The detected current values (instantaneous values) of the currents to be monitored are then converted into discrete, digitized current values, as shown in box 14 of FIG. 1.

From the digitized, discrete current values of the electrical currents to be monitored, the sum current values are calculated, for example by addition, as shown in box 16 of FIG. 1. As shown in box 18 of the block diagram, blocks are now formed from the total current values as a function of the phase position of the line frequency of a line voltage signal, the length of the blocks depending on the phase position of the line voltage signal and preferably a period (or an integral multiple of a period) Mains frequency. The block formation can be overlapping or sequential. In order to form the blocks of., The calculated digital sum current values in synchronism with the line frequency of the line voltage, a synchronization signal is provided, as shown in box 20, the synchronization signal being obtained from a detection of the line frequency of the line voltage signal, as in box 22 is shown. The synchronizing signal preferably indicates a period of the mains voltage in order to form the block from the calculated, digital total current values, the synchronizing signal preferably being obtained by detecting two identical zero crossings of the mains voltage signal, so that one block always contains all calculated, digital total current values during a period of mains voltage. It should be obvious that the period of the line voltage can also be determined in any other suitable way from the course of the line voltage signal.

Furthermore, it should be noted that, according to the present invention, it is also possible to carry out the block formation according to box 18 of the flowchart of FIG. 1 over several periods of the mains voltage signal, which on the one hand makes the accuracy of the method according to the invention for fault current monitoring in one electrical AC network is increased, but on the other hand, the further processing of the blocks from the calculated, digital total current values is made considerably more complex.

As shown in box 24, the calculated, digitized total current values are now calculated using a suitable transformation, e.g. B. a Fourier transform (DFT = discrete Fourier transform or FFT = fast Fourier transform), broken down into its spectral components.

At this point in the method according to the invention for residual current monitoring in an electrical AC network, a different weighting of the active and reactive current components of the spectrally sum current values are carried out, for example, by multiplying the real or imaginary part of the respective spectral line of a sum current value by a specific weighting factor, as is optionally provided in box 26 of FIG. 1. As a weighting specification (box 28) it can be provided, for example, to double the tripping threshold for capacitive (or inductive) reactive currents, so that, for example, the imaginary part of the component at the mains frequency, e.g. B. at 50 Hz, multiplied by 0.5.

The optional weighting (box 26) of the respective spectral components of the total current values, if this is carried out, or otherwise the Fourier transformation is now generally followed by limit value monitoring of the spectral components of the blocks with regard to exceeding spectral limit values, as shown in box 32 is to evaluate the dangerousness of the fault current from the spectrally decomposed total current values. In the event of a limit being exceeded, a predetermined action is then carried out, an optical or acoustic warning message being able to be generated as the action, a message being transmitted via a corresponding network, or a protective function, e.g. B. an all-pole shutdown can be triggered.

In the flow diagram of Fig. 1 further shows that before the limit monitoring the spectral proportions of the blocks with respect to an exceeding of spectral limit values (box 32) optionally also a so-called Abbil ^¬-making function can be performed, as indicated by box 30 of the flowchart of Fig. 1 is shown. The following explains in detail which of them Prerequisites for this step of performing an imaging function (box 30) is necessary and is carried out according to the invention.

Assuming that the fundamental wave of the spectrally decomposed total current values corresponds to the network frequency of 50 Hz, for example, the amount of the spectral weighting of the individual spectral lines shown in FIG. 2 is obtained after the discrete Fourier transformation. If one now assumes that the signal to be measured, i. H. If the calculated total current or the calculated total current values (see box 16), exactly the network frequency of 50 Hz or an integral multiple thereof, then the correct value of the relevant spectral line is determined using the discrete Fourier transformation. In this case, it is not necessary to perform the mapping function (box 30 of Fig. 1).

However, is the signal frequency of the total current, i. H. of the total current values, for example at a frequency that does not correspond to an integral multiple of the basic network frequency, as can be seen from FIG. 2, the switch-off threshold is raised significantly at this frequency due to the lower sensitivity of the spectral lines, which correspond to an integral multiple of the basic network frequency.

In this case, only a relatively coarse threshold value is realized in the time domain in the version of an FI circuit breaker to be implemented here. The other two provided threshold values relate to spectral representations of the fault current. Represent these spectral lines calculated by means of a Fourier transformation (FFT) a spectral value (consisting of real and imaginary part) a certain frequency range. In the specific case, this range extends over 50 Hz.

It would be ideal if a monofrequency fault current with the amplitude 1, regardless of the exact frequency, would also supply a value of 1 in the area of a spectral line as a spectral value. However, this is not the case. The actual amplitude relationships can be found in FIG. 2.

In the middle of the 50 Hz range, the amount of the 50 Hz spectral line is exactly 1. Towards the edges, the amount drops to approx. 63% (0.63). This means that a fault current with a frequency of 75 Hz would have a switch-off threshold that is 37% higher than at the nominal frequency of 50 Hz, since, as shown in FIG. 2, a 75 Hz signal, for example, is uniformly with a value of approximately Divides 0.63 on the neighboring 50Hz and 100Hz spectral line.

Thus, for example, is the signal frequency of the sum current at a frequency of 75 Hz (see. The direction indicated with a circle position in Fig. 2), and starting from a mains frequency of 50 Hz, the Ab ^¬ depends switching threshold between the spectral significantly on the signal frequency.

Therefore, in the present invention, after the blocks have been broken down into spectral components, a correction of the detection sensitivity for fault currents with frequencies between successive multiples of the mains frequency is carried out by spectral values that correspond to the neighboring beard spectral lines are assigned, combined. This combination is commonly referred to as "mapping" hereinafter (box 30).

The combined spectral amplitude values are then monitored in the present invention in order to assess or assess the dangerousness of the fault current, as has already been discussed in detail using box 32 above.

In order to be able to solve the above-mentioned problem regarding fault currents with frequencies between successive multiples of the mains frequency by means of a "mapping", two directly adjacent spectral lines have to be offset or combined with one another in such a way that a 50 Hz wide range with essentially 'constant' Amplitude arises. This area with an essentially constant amplitude can then be used for the actual threshold value comparison. Outside the constant range, however, the amplitude should drop as quickly as possible to a value of 0 (zero) so that a targeted spectral evaluation remains possible.

However, the result of the calculation must not depend on the phase position of the individual signals. Therefore, the real and imaginary part of the spectral lines under consideration cannot be used in the calculation without exact examination of the result.

A preferred implementation according to the present invention of a calculation or combination of spectral amplitudes which are assigned to adjacent spectral lines now consists in the two amounts (amount squares) of to combine and preferably add adjacent spectral lines in each case (box 30 of the flow chart of FIG. 1). This gives spectral ranges between adjacent spectral lines, ie between adjacent spectral lines with an integral multiple of the basic network frequency, with an approximately constant sensitivity for frequency-independent switch-off limits within these spectral ranges.

A relatively simple approach to reach this area with a constant amplitude is possible via the following relationship of the addition of the squares:

B (kf = Jfc, • (RE (kf + IM (kf) + k ₂ ■ [üE (k +1) ² + Iλf (k + lf)

This relatively simple approach links the squares of the amounts of two neighboring spectral lines (k; k + 1), which have an integer multiple of the network frequency. It should be noted that the above-mentioned link is selected only as an example for the present invention and, in principle, any other suitable link with which an area with the most constant amplitude possible can be used can be used. However, it should be noted that the requirements such. B. the computing power etc. of the respective electronic components that are used to carry out the method according to the invention increase significantly if a mathematically complex link is selected.

The spectral weighting between two adjacent Spekt ^¬ rallinien in FIG. 3 based on the curves I, II and III illustrated in principle, the course of the amount of I 50 Hz spectral line, the curve II represents the magnitude of the 100 Hz spectral line and the curve III the combination of the squares of the magnitudes of the two spectral lines.

The ideal would be an absolute value function that has a value of 1 in the range between 50 and 100 Hz and a value of 0 outside. By linking the squares of magnitude, the magnitude function (gradient III) is obtained from the two spectral lines (curve I, II). The remaining ripple in the amount in this case is approximately a maximum of ± 5%.

The resulting value of the detection sensitivity for fault currents is therefore a good measure of the existing signal amplitude between the two adjacent discrete frequencies when added. The maximum uncertainty of approximately ± 5% is practically imperceptible in the synchronous operating mode, but leads to additional uncertainty when evaluating the switch-off threshold in asynchronous operation.

According to the present invention, the magnitude function (curve III) provides information about the sum of the signal amplitudes present in the interval between the adjacent frequencies, i. H. between adjacent spectral lines with an integer multiple of the basic network frequency, which is, for example, 50 Hz.

The suppression of frequency components outside the 50 Hz window under consideration is only insignificantly worse due to the selected link. If another fault current line lies in the most unfavorable part of the directly adjacent spectral line, it is still suppressed by a factor of at least 3. This form of overlap can in principle be carried out for all AC components starting from 50 Hz up to and including the 750 Hz line. By adding two spectral lines, however, the signal to noise ratio is significantly deteriorated. The noise increases by a factor of \ 2, while the signal (consisting of a line) remains unchanged.

At the finest threshold (50 Hz), this can pose a problem in that the signal-to-noise ratio is then no longer large enough to be able to implement a switch-off threshold for the fault current of 10 mA, for example. The 50Hz decision maker with the finest threshold must therefore use the non-overlapped value from the Fourier transformation (FFT) directly. However, so that the range between 50 Hz and 100 Hz is not incorrectly evaluated, the overlap value must still be calculated. This overlap value is not saved in the previously 50 Hz line, but in the 100 Hz line.

The entire mapping, which is carried out by an overlap, is shown by way of example in FIG. 4.

With this measure it is now possible to set the 50 Hz threshold lower than the threshold value between 50 Hz and 100 Hz. With the 50 Hz line you are within a range of the thermal noise limit given by the bandwidth of 50 Hz. All others (higher frequency lines) have an effective noise bandwidth of 100 Hz and are therefore worse by a factor of ^ 2 than the 50 Hz line. In the present invention, the sum value obtained of the signal amplitudes present in the interval between the two adjacent frequencies is then monitored, for example by a comparator, for exceeding a certain limit (see box 32). According to the present invention, it is possible to implement different switch-off thresholds for different frequency ranges. This means that high-frequency fault currents resulting from switched elements can be weighted less, in order to reduce the frequency of false tripping without reducing the safety for people. With the fault current monitoring system according to the invention, fault currents whose frequency does not match an integral multiple of the mains frequency can thus also be safely and reliably evaluated.

With the method according to the invention, which has been described with reference to FIG. 1, it is now also possible to specifically detect and evaluate direct currents since, in accordance with the present invention, sensors capable of direct current can now be used in signal detection by individual sensors.

The Fourier transformation (FFT) provides the corresponding DC component, which can either be overlapped with the 50 Hz line or simply subjected to a limit value analysis directly as a DC component. This is done analogously to all other spectral lines. There is of course no active / reactive current subdivision when considering the limit value of a direct current component (DC).

With the possibility of being able to implement any spectral weighting functions, it is also possible to reproduce the line of the physiological risk to humans as a function of frequency. If this is done, a high level of security for humans is combined with an optimally low frequency for faulty tripping and thus a high level of acceptance of the protection system.

According to the present invention, two weighting factors (one each for active and reactive components) and a switch-off limit value for the amount can be specified for each of the calculated spectral lines. The possibility of being able to adjust the limit values during operation based on the measured spectral lines can achieve an optimal protective effect with a low number of false triggers.

As shown in box 32 of FIG. 1, a predetermined action is carried out in the event of a limit being exceeded, an optical or acoustic warning message being able to be generated as an action, a message being transmitted via a corresponding network or a protective function, e.g. B. an all-pole shutdown can be triggered.

In practice, it is advantageous to use the current spectral line directly on the mains frequency, e.g. B. at 50 Hz, are also directly (without a figure). To give a separate limit monitoring to monitor this main line particularly well and undisturbed by the neighboring lines. This is particularly useful if the network frequency is in a physiologically very unfavorable frequency range. A main advantage of the present invention over the prior art is that the method according to the invention for residual current monitoring in an electrical AC network with a predetermined network frequency now makes it possible to assess the hazard potential of all spectral components of currents to be monitored in accordance with the physiological findings. The greatest possible safety for the user can be reconciled with the lowest possible number of false triggers.

Even in critical applications, e.g. B. when system-related high fault currents occur at certain frequencies, such as. B. at a PWM frequency in three-phase drives in which a protective function could no longer be adequately guaranteed, the method according to the invention can still achieve sufficiently good protection by the relevant frequency (s), ie. H. only these, completely hidden and less weighted. As long as the problematic active current components are not on the line frequency line of 50 Hz, for example, effective protection for people can still be obtained as far as possible.

Claims

Patent claims

1. Method for fault current monitoring in an electrical alternating current network with a specified network frequency, with the following steps:

Detecting (12a-d) current values of electrical currents to be monitored,

Converting (14) the recorded current values into digitized current values,

Calculating (16) total current values from the digitized current values,

Forming (18) blocks from the total current values depending on the phase position of a mains voltage signal,

Spectral decomposition (24) of the blocks into spectral components, and

Monitoring (32) of the spectral components of the blocks with regard to exceeding spectral limit values in order to evaluate the danger of the fault current.

2. The method according to claim 1, in which, after breaking down (24) the blocks into spectral components, a correction (30) of the detection sensitivity for fault currents with frequencies between successive multiples of the mains frequency is carried out by using spectral amplitude values that are assigned to the adjacent spectral lines , can be combined with each other.

. Method according to claim 2, in which the combined spectral amplitude values are used to evaluate the danger of a fault current.

4. The method according to claim 2 or 3, in which the squares of spectral amplitude values assigned to the adjacent spectral lines are added.

5. The method according to claim 4, in which the added spectral amplitude values are used to evaluate the danger of the fault current.

6. Method according to one of the preceding claims, in which the spectral decomposition (24) of the blocks is carried out using a discrete Fourier transformation.

7. Method according to one of the preceding claims, in which the spectral components are weighted using frequency-dependent weighting specifications (26).

8. The method according to claim 7, in which a different weighting (26) of the real part and imaginary part of the spectral components is carried out.

9. The method according to claim 8, in which a different weighting of the real part and imaginary part of the spectral components is carried out in order to evaluate the danger potential of the fault current with regard to physiological specifications and / or material protection specifications depending on the frequency.

0. Method according to one of the preceding claims, in which the blocks are formed from the total current values depending on the phase position of a mains voltage signal, the phase position being obtained from two identical zero crossings of the mains voltage signal.

11. Device for residual current monitoring in an electrical alternating current network with a specified network frequency, with the following features:

a device for recording current values of electrical currents to be monitored,

a device for converting the recorded current values into digitized current values,

a device for calculating total current values from the digitized current values,

a device for forming blocks from the total current values depending on the phase position of a mains voltage signal,

a device for the spectral decomposition of the blocks into spectral components, and

a device for monitoring the spectral components of the blocks with regard to whether spectral limit values are exceeded in order to assess the danger of the fault current.

2. Device according to claim 11, in which, after breaking down (24) the blocks into spectral components, a correction (30) of the detection sensitivity for fault currents with frequencies between successive multiples of the network frequency is carried out by using spectral amplitude values that are assigned to the adjacent spectral lines , can be combined with each other.

13. Device according to claim 12, in which the combined spectral amplitude values are used to evaluate the danger of a fault current.

14. Device according to claim 12 or 13, in which the absolute squares of spectral amplitude values assigned to ^the adjacent spectral lines are added.

15. Device according to claim 14, in which the added spectral amplitude values are used to evaluate the dangerousness of the fault current.

16. Device according to one of claims 11 - 15, in which the spectral decomposition (24) of the blocks takes place by means of a discrete Fourier transformation.

17. Device according to one of claims 11 - 16, in which the spectral components are weighted using frequency-dependent weighting specifications (26).

18. The device according to claim 17, in which a ^different weighting (26) of the real part and imaginary part of the spectral components is carried out.

9. Device according to claim 18, in which a different weighting of the real part and imaginary part of the spectral components is carried out in order to evaluate the danger potential of the fault current with regard to physiological specifications and / or material protection specifications depending on the frequency.

20. Device according to one of claims 11 - 19, in which the blocks are formed from the total current values depending on the phase position of a mains voltage signal, the phase position being obtained from two similar zero crossings of the mains voltage signal.